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Nanostructured Upconvertors for Advanced Solar Energy Harvesting. The efficiency of many solar energy conversion processes, such as solar photovoltaic and solar hydrogen, can be improved by management of the solar spectrum. One photon management strategy is up-conversion, whereby two lower energy, unusable photons are conjoined to bring about a higher energy photon. Photochemical up-conversion, where light harvesting and energy-pooling is performed in organic molecules, has been rapidly advanced ....Nanostructured Upconvertors for Advanced Solar Energy Harvesting. The efficiency of many solar energy conversion processes, such as solar photovoltaic and solar hydrogen, can be improved by management of the solar spectrum. One photon management strategy is up-conversion, whereby two lower energy, unusable photons are conjoined to bring about a higher energy photon. Photochemical up-conversion, where light harvesting and energy-pooling is performed in organic molecules, has been rapidly advanced in recent years, and promises to deliver the efficiencies required to find real-world application. This project brings together laser spectroscopy, organic and materials chemistry and nanotechnology to realise efficient up-convertors which will be applied to solar cells and solar fuels.Read moreRead less
Expanding the molecular tool set for structural studies of proteins and their complexes. Many applications in medical science and drug development depend on our ability to determine the 3D structures of proteins, protein assemblies and protein-ligand complexes. This project will develop novel lanthanide-binding tags and crosslinking agents that can be coupled to unnatural amino acids introduced into proteins with advanced protein chemistry techniques. These new tools will facilitate the collecti ....Expanding the molecular tool set for structural studies of proteins and their complexes. Many applications in medical science and drug development depend on our ability to determine the 3D structures of proteins, protein assemblies and protein-ligand complexes. This project will develop novel lanthanide-binding tags and crosslinking agents that can be coupled to unnatural amino acids introduced into proteins with advanced protein chemistry techniques. These new tools will facilitate the collection of structure restraints by nuclear magnetic resonance (NMR), electron paramagnetic resonance (EPR) and mass spectrometry, which are needed to generate accurate models of proteins and their complexes with other molecules. Major beneficial outcome will include an increase in the number of protein targets amenable to rational drug design and improved methods for generating new drug leads.Read moreRead less
Molecular switching nanomaterials for modern technology. This project aims to develop a new class of functional materials with integrated molecular switching capacity. Molecule-based switching materials are actively pursued in cutting-edge sensory, information storage and nanophotonic devices. This project expects to drive the advancement of modern memory-switching device and sensor technologies. An expected outcome of this project is to define a new sophisticated class of nanomaterials with in ....Molecular switching nanomaterials for modern technology. This project aims to develop a new class of functional materials with integrated molecular switching capacity. Molecule-based switching materials are actively pursued in cutting-edge sensory, information storage and nanophotonic devices. This project expects to drive the advancement of modern memory-switching device and sensor technologies. An expected outcome of this project is to define a new sophisticated class of nanomaterials with inbuilt molecular switching features in active pursuit of modern nanotechnologies and evolving key fundamental concepts which underpin nano-scale switching.Read moreRead less
Broadband compensation of nonlinear signal distortion in optical fibre communications. This project will investigate novel optical technologies for overcoming the approaching data capacity limits of global optical communication networks that are caused by transmission errors from nonlinear signal distortion in optical fibre. The research will show that light propagation through specially designed waveguides can cancel the distortion.
Functional molecular nanomaterials. The design and construction of advanced nanomaterials is a key step in the push towards more efficient energy systems and smarter technologies. Through the strategic assembly of new classes of molecular nanomaterials, this project will lead to important fundamental advances in nanoscience and will underpin a range of new high-level technologies.